Organization of signal segments supporting sensed features

ABSTRACT

The managing of sensed signals used to sense features of physical entities over time. A computer-navigable graph of sensed features is generated. For each sensed feature, a signal segment that was used to sense that feature is computer-associated with the sensed feature. Later, the graph of sensed features may be navigated to that features. The resulting signal segment(s) may then be access allowing for rendering of the signal evidence that resulted in the sensed feature. Accordingly, the principles described herein allow for sophisticated and organized navigation to sensed features of physical entities in the physical world, and allow for rapid rendering of the signals that evidence that sensed features.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional application62/447,803 filed Jan. 18, 2017, titled “ORGANIZATION OF SIGNAL SEGMENTSSUPPORTING SENSED FEATURES”, which is incorporated herein by referencein its entirety.

BACKGROUND

Computing systems and associated networks have greatly revolutionizedour world. At first, computing systems were only able to perform simpletasks. However, as processing power has increased and becomeincreasingly available, the complexity of tasks performed by a computingsystem has greatly increased. Likewise, the hardware complexity andcapability of computing systems has greatly increased, as exemplifiedwith cloud computing that is supported by large data centers.

For a long period of time, computing systems just did essentially whatthey were told by their instructions or software. However, software andthe employment of hardware is becoming so advanced that computingsystems are now, more than ever before, capable of some level ofdecision making at higher levels. At present, in some respects, thelevel of decision making can approach, rival, or even exceed thecapability of the human brain to make decisions. In other words,computing systems are now capable of employing some level of artificialintelligence.

One example of artificial intelligence is the recognition of externalstimuli from the physical world. For instance, voice recognitiontechnology has improved greatly allowing for high degree of accuracy indetecting words that are being spoken, and even the identity of theperson that is speaking. Likewise, computer vision allows computingsystems to automatically identify objects within a particular picture orframe of video, or recognize human activity across a series of videoframes. As an example, face recognition technology allows computingsystems to recognize faces, and activity recognition technology allowscomputing systems to know whether two proximate people are workingtogether.

Each of these technologies may employ deep learning (Deep NeuralNetwork-based and reinforcement-based learning mechanisms) and machinelearning algorithms to learn from experience what is making a sound, andobjects or people that are within an image, thereby improving accuracyof recognition over time. In the area of recognizing objects within amore complex imaged scene with large numbers of visual distractions,advanced computer vision technology now exceeds the capability of ahuman being to quickly and accurately recognize objects of interestwithin that scene. Hardware, such as matrix transformation hardware inconventional graphical processing units (GPUs), may also contribute tothe rapid speed in object recognition in the context of deep neuralnetworks.

The subject matter claimed herein is not limited to embodiments thatsolve any disadvantages or that operate only in environments such asthose described above. Rather, this background is only provided toillustrate one exemplary technology area where some embodimentsdescribed herein may be practiced.

BRIEF SUMMARY

Embodiments described herein are directed towards the managing of sensedsignals used to sense features of physical entities over time. Themethod includes creating a computer-navigable graph of a sensed featuresof sensed physical entities over time. The computer-navigable graph maybe any collection of sensed features that are associated in an organizedway that may be navigated to by a computing system. The navigation mayoccur, for instance, in response to user input, in response to a userquery, as part of a machine-learning algorithm, or for any other reason.In addition, for at least one of the sensed features for at least one ofthe sensed plurality of entities, at least one signal segment iscomputer-associated with the sensed feature such thatcomputer-navigation to the sensed feature also allows forcomputer-navigation to the signal segment.

Later, automatically or in response to user input (such as a query), thegraph of sensed features may be navigated to one or more sensedfeatures. The resulting sensed signal(s) may then be access allowing forrendering of the signal evidence that resulted in the sensed feature.Accordingly, the principles described herein allow for sophisticated andorganized navigation to sensed features of physical entities in thephysical world, and allow for rapid rendering of the signals thatevidence that sensed features. This enables complex computing andqueries to be performed on the physical world, and for quick focusing onthe portions of the physical world that are of interest to thatcomputation.

This summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used as an aid in determining the scope of the claimed subjectmatter.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to describe the manner in which the above-recited and otheradvantages and features of the invention can be obtained, a moreparticular description of the invention briefly described above will berendered by reference to specific embodiments thereof which areillustrated in the appended drawings. Understanding that these drawingsdepict only typical embodiments of the invention and are not thereforeto be considered to be limiting of its scope, the invention will bedescribed and explained with additional specificity and detail throughthe use of the accompanying drawings in which:

FIG. 1 illustrates an example computer system in which the principlesdescribed herein may be employed;

FIG. 2 illustrates a flowchart of a method for managing sensed signalsused to sense features of physical entities over time;

FIG. 3 illustrates an architecture in which the method of FIG. 2 may bepracticed and includes the navigable graph of sensed features and theassociated sensor signals;

FIG. 4 illustrates an environment in which the principles describedherein may operate, which includes a physical space that includesmultiple physical entities and multiple sensors, a recognition componentthat senses features of physical entities within the physical space, anda feature store that stores sensed features of such physical entities,such that computation and querying may be performed against thosefeatures;

FIG. 5 illustrates a flowchart of a method for tracking physicalentities within a location and may be performed in the environment ofFIG. 4;

FIG. 6 illustrates an entity tracking data structure that may be used toassist in performing the method of FIG. 5, and which may be used tolater perform queries on the tracked physical entities; and

FIG. 7 illustrates a flowchart of a method for efficiently renderingsignal segments of interest.

DETAILED DESCRIPTION

Embodiments described herein are directed towards the managing of sensedsignals used to sense features of physical entities over time. Themethod includes creating a computer-navigable graph of a sensed featuresof sensed physical entities over time. The computer-navigable graph maybe any collection of sensed features that are associated in an organizedway that may be navigated to by a computing system. The navigation mayoccur, for instance, in response to user input, in response to a userquery, as part of a machine-learning algorithm, or for any other reason.In addition, for at least one of the sensed features for at least one ofthe sensed plurality of entities, at least one signal segment iscomputer-associated with the sensed feature such thatcomputer-navigation to the sensed feature also allows forcomputer-navigation to the signal segment.

Later, automatically or in response to user input (such as a query), thegraph of sensed features may be navigated to one or more sensedfeatures. The resulting sensed signal(s) may then be access allowing forrendering of the signal evidence that resulted in the sensed feature.Accordingly, the principles described herein allow for sophisticated andorganized navigation to sensed features of physical entities in thephysical world, and allow for rapid rendering of the signals thatevidence that sensed features. This enables complex computing andqueries to be performed on the physical world, and for quick focusing onthe portions of the physical world that are of interest to thatcomputation.

Because the principles described herein operate in the context of acomputing system, a computing system will be described with respect toFIG. 1. Thereafter, the principles of managing a navigable graph ofsensed features and associated signal segments that evidence the sensedfeatures will be described with respect to FIGS. 2 through 6. Then, thenavigation of that navigable graph to acquire or reconstruct the signalsegment(s) of interest will be described with respect to FIG. 7.

Computing systems are now increasingly taking a wide variety of forms.Computing systems may, for example, be handheld devices, appliances,laptop computers, desktop computers, mainframes, distributed computingsystems, datacenters, or even devices that have not conventionally beenconsidered a computing system, such as wearables (e.g., glasses,watches, bands, and so forth). In this description and in the claims,the term “computing system” is defined broadly as including any deviceor system (or combination thereof) that includes at least one physicaland tangible processor, and a physical and tangible memory capable ofhaving thereon computer-executable instructions that may be executed bya processor. The memory may take any form and may depend on the natureand form of the computing system. A computing system may be distributedover a network environment and may include multiple constituentcomputing systems.

As illustrated in FIG. 1, in its most basic configuration, a computingsystem 100 typically includes at least one hardware processing unit 102and memory 104. The memory 104 may be physical system memory, which maybe volatile, non-volatile, or some combination of the two. The term“memory” may also be used herein to refer to non-volatile mass storagesuch as physical storage media. If the computing system is distributed,the processing, memory and/or storage capability may be distributed aswell.

The computing system 100 has thereon multiple structures often referredto as an “executable component”. For instance, the memory 104 of thecomputing system 100 is illustrated as including executable component106. The term “executable component” is the name for a structure that iswell understood to one of ordinary skill in the art in the field ofcomputing as being a structure that can be software, hardware, or acombination thereof. For instance, when implemented in software, one ofordinary skill in the art would understand that the structure of anexecutable component may include software objects, routines, methodsthat may be executed on the computing system, whether such an executablecomponent exists in the heap of a computing system, or whether theexecutable component exists on computer-readable storage media.

In such a case, one of ordinary skill in the art will recognize that thestructure of the executable component exists on a computer-readablemedium such that, when interpreted by one or more processors of acomputing system (e.g., by a processor thread), the computing system iscaused to perform a function. Such structure may be computer-readabledirectly by the processors (as is the case if the executable componentwere binary). Alternatively, the structure may be structured to beinterpretable and/or compiled (whether in a single stage or in multiplestages) so as to generate such binary that is directly interpretable bythe processors. Such an understanding of example structures of anexecutable component is well within the understanding of one of ordinaryskill in the art of computing when using the term “executablecomponent”.

The term “executable component” is also well understood by one ofordinary skill as including structures that are implemented exclusivelyor near-exclusively in hardware, such as within a field programmablegate array (FPGA), an application specific integrated circuit (ASIC), orany other specialized circuit. Accordingly, the term “executablecomponent” is a term for a structure that is well understood by those ofordinary skill in the art of computing, whether implemented in software,hardware, or a combination. In this description, the term “component”may also be used. As used in this description and in the case, this term(regardless of whether the term is modified with one or more modifiers)is also intended to be synonymous with the term “executable component”or be specific types of such an “executable component”, and thus alsohave a structure that is well understood by those of ordinary skill inthe art of computing.

In the description that follows, embodiments are described withreference to acts that are performed by one or more computing systems.If such acts are implemented in software, one or more processors (of theassociated computing system that performs the act) direct the operationof the computing system in response to having executedcomputer-executable instructions that constitute an executablecomponent. For example, such computer-executable instructions may beembodied on one or more computer-readable media that form a computerprogram product. An example of such an operation involves themanipulation of data.

The computer-executable instructions (and the manipulated data) may bestored in the memory 104 of the computing system 100. Computing system100 may also contain communication channels 108 that allow the computingsystem 100 to communicate with other computing systems over, forexample, network 110.

While not all computing systems require a user interface, in someembodiments, the computing system 100 includes a user interface 112 foruse in interfacing with a user. The user interface 112 may includeoutput mechanisms 112A as well as input mechanisms 112B. The principlesdescribed herein are not limited to the precise output mechanisms 112Aor input mechanisms 112B as such will depend on the nature of thedevice. However, output mechanisms 112A might include, for instance,speakers, displays, tactile output, holograms, virtual reality, and soforth. Examples of input mechanisms 112B might include, for instance,microphones, touchscreens, holograms, virtual reality, cameras,keyboards, mouse of other pointer input, sensors of any type, and soforth.

Embodiments described herein may comprise or utilize a special purposeor general-purpose computing system including computer hardware, suchas, for example, one or more processors and system memory, as discussedin greater detail below. Embodiments described herein also includephysical and other computer-readable media for carrying or storingcomputer-executable instructions and/or data structures. Suchcomputer-readable media can be any available media that can be accessedby a general purpose or special purpose computing system.Computer-readable media that store computer-executable instructions arephysical storage media. Computer-readable media that carrycomputer-executable instructions are transmission media. Thus, by way ofexample, and not limitation, embodiments can comprise at least twodistinctly different kinds of computer-readable media: storage media andtransmission media.

Computer-readable storage media includes RAM, ROM, EEPROM, CD-ROM orother optical disk storage, magnetic disk storage or other magneticstorage devices, or any other physical and tangible storage medium whichcan be used to store desired program code means in the form ofcomputer-executable instructions or data structures and which can beaccessed by a general purpose or special purpose computing system.

A “network” is defined as one or more data links that enable thetransport of electronic data between computing systems and/or modulesand/or other electronic devices. When information is transferred orprovided over a network or another communications connection (eitherhardwired, wireless, or a combination of hardwired or wireless) to acomputing system, the computing system properly views the connection asa transmission medium. Transmissions media can include a network and/ordata links which can be used to carry desired program code means in theform of computer-executable instructions or data structures and whichcan be accessed by a general purpose or special purpose computingsystem. Combinations of the above should also be included within thescope of computer-readable media.

Further, upon reaching various computing system components, program codemeans in the form of computer-executable instructions or data structurescan be transferred automatically from transmission media to storagemedia (or vice versa). For example, computer-executable instructions ordata structures received over a network or data link can be buffered inRAM within a network interface module (e.g., a “NIC”), and theneventually transferred to computing system RAM and/or to less volatilestorage media at a computing system. Thus, it should be understood thatreadable media can be included in computing system components that also(or even primarily) utilize transmission media.

Computer-executable instructions comprise, for example, instructions anddata which, when executed at a processor, cause a general purposecomputing system, special purpose computing system, or special purposeprocessing device to perform a certain function or group of functions.Alternatively, or in addition, the computer-executable instructions mayconfigure the computing system to perform a certain function or group offunctions. The computer executable instructions may be, for example,binaries or even instructions that undergo some translation (such ascompilation) before direct execution by the processors, such asintermediate format instructions such as assembly language, or evensource code.

Those skilled in the art will appreciate that the invention may bepracticed in network computing environments with many types of computingsystem configurations, including, personal computers, desktop computers,laptop computers, message processors, hand-held devices, multi-processorsystems, microprocessor-based or programmable consumer electronics,network PCs, minicomputers, mainframe computers, mobile telephones,PDAs, pagers, routers, switches, datacenters, wearables (such as glassesor watches) and the like. The invention may also be practiced indistributed system environments where local and remote computingsystems, which are linked (either by hardwired data links, wireless datalinks, or by a combination of hardwired and wireless data links) througha network, both perform tasks. In a distributed system environment,program modules may be located in both local and remote memory storagedevices.

Those skilled in the art will also appreciate that the invention may bepracticed in a cloud computing environment. Cloud computing environmentsmay be distributed, although this is not required. When distributed,cloud computing environments may be distributed internationally withinan organization and/or have components possessed across multipleorganizations. In this description and the following claims, “cloudcomputing” is defined as a model for enabling on-demand network accessto a shared pool of configurable computing resources (e.g., networks,servers, storage, applications, and services). The definition of “cloudcomputing” is not limited to any of the other numerous advantages thatcan be obtained from such a model when properly deployed.

For instance, cloud computing is currently employed in the marketplaceso as to offer ubiquitous and convenient on-demand access to the sharedpool of configurable computing resources. Furthermore, the shared poolof configurable computing resources can be rapidly provisioned viavirtualization and released with low management effort or serviceprovider interaction, and then scaled accordingly.

A cloud computing model can be composed of various characteristics suchas on-demand self-service, broad network access, resource pooling, rapidelasticity, measured service, and so forth. A cloud computing model mayalso come in the form of various service models such as, for example,Software as a Service (“SaaS”), Platform as a Service (“PaaS”), andInfrastructure as a Service (“IaaS”). The cloud computing model may alsobe deployed using different deployment models such as private cloud,community cloud, public cloud, hybrid cloud, and so forth. In thisdescription and in the claims, a “cloud computing environment” is anenvironment in which cloud computing is employed.

FIG. 2 illustrates a flowchart of a method 200 for managing sensedsignals used to sense features of physical entities over time. Themethod 200 includes creating a computer-navigable graph of a sensedfeatures of sensed physical entities over time (act 201). For instance,FIG. 3 illustrates an architecture 300 in which the method 200 may bepracticed. The architecture 300 includes the computer-navigable graph310. The computer-navigable graph 310 may be any collection of sensedfeatures that are associated in an organized way that may be navigatedto by a computing system. The navigation may occur, for instance, inresponse to user input, in response to a user query, as part of amachine-learning algorithm, or for any other reason.

In addition, for at least one (and preferably many) of the sensedfeatures for at least one of the sensed plurality of entities, at leastone signal segment is computer-associated with the sensed feature (act202) such that computer-navigation to the sensed feature also allows forcomputer-navigation to the signal segment. For instance, referring toFIG. 2, the navigable graph of sensed features 310 is acomputing-associated (as represented by arrow 315) with the signalsegments 320 that were used to sense the corresponding sensed features.As represented by arrow 210, the association of the sensed signal withthe associated signal segment may be performed continuously, thusresulting in an expanding graph, and an expanding collection of signalsegments. That said, as described further below, garbage collectionprocesses may be used to clean up sensed features and/or signal segmentsthat are outdated or no longer of interest.

The signal segment may include multiple pieces of metadata such as, forinstance, an identification of the sensor or sensors that generated thesignal segment. The signal segment need not include all of the signalsthat were generated by that sensor, and for brevity, may perhaps includeonly those portions of the signal that were used to sense the sensedfeature of the particular physical entity. In that case, the metadatamay include a description of the portion of the original signal segmentthat was stored.

The sensed signal may be any type of signal that is generated by asensor. Examples include video, image, and audio signals. However, thevariety of signals is not limited to those that can be sensed by a humanbeing. For instance, the signal segment might represented a transformedversion of the signal generated by the sensor to allow for humanobservations of better human focus. Such transformations might includefiltering, such a filtering based on frequency, or quantization. Suchtransformation might also include amplification, frequency shifting,speed adjustment, magnifying, amplitude adjustment, and so forth.

In order to allow for reduction in storage requirements as well asproper focus on the signal of interest, perhaps only a portion of thesignal segment is stored. For instance, if a video signal, perhaps onlya portion of the frames of the video are stored. Furthermore, for anygiven image, perhaps only the relevant portion of the frame is stored.Likewise, if the sensor signal was an image, perhaps only the relevantportion of the image is stored. The recognition service that uses thesignal segment to sense a feature is aware of which portion of thesignal segment that was used to sense a feature. Accordingly, arecognition service can specifically carve out the relevant portion ofthe signal for any given sensed feature.

A specific example of the formulation of a sensed feature graph andassociated signal segments will now be described with respect to FIGS. 4through 6. Thereafter, a method for navigating the navigable graph ofsensed features and rendering the associated signal segment will bedescribed with respect to FIG. 7.

FIG. 4 illustrates an environment 400 in which the principles describedherein may operate. The environment 400 includes a physical space 401that includes multiple physical entities 410, which may be any extantobject, person, or thing that emits or reflects physical signals (suchas electromagnetic radiation or acoustics) that has a pattern that maybe used to potentially identify one or more physical features (alsocalled herein states) of the respective object, person, or thing. Anexample of such potentially identifying electromagnetic radiation isvisible light that has a light pattern (e.g., a still image or video)from which characteristics of visible entities may be ascertained. Suchlight pattern may be any temporal, spatial, or even higher-dimensionalspace. An example of such acoustics may the voice of a human being, thesound of an object in normal operation or undergoing an activity orevent, or a reflected acoustic echo.

The environment 400 also includes sensors 420 that receive physicalsignals from the physical entities 410. The sensors need not, of course,pick up every physical signal that the physical entity emits orreflects. For instance, a visible light camera (still or video) iscapable of receiving electromagnetic radiation in the form of visiblelight and converting such signals into processable form, but cannot pickup all electromagnetic radiation of any frequency since cameras all havea finite dynamic range. Acoustic sensors likewise have limited dynamicrange designed for certain frequency ranges. In any case, the sensors420 provide (as represented by arrow 429) resulting sensor signals to arecognition component 430.

The recognition component 430 at least estimates (e.g., estimates orrecognizes) one or more features of the physical entities 410 within thelocation based on patterns detected in the received sensor signals. Therecognition component 430 may also generate a confidence levelassociated with the “at least an estimation” of a feature of thephysical entity. If that confidence level is less than 100%, then the“at least an estimation” is just an estimation. If that confidence levelis 100%, then the “at least an estimation” is really more than anestimation—it is a recognition. In the remainder of this description andin the claims, a feature that is “at least estimated” will also bereferred to as a “sensed” feature to promote clarity. This is consistentwith the ordinary usage of the term “sense” since a feature that is“sensed” is not always present with complete certainty. The recognitioncomponent 430 may employ deep learning (Deep Neural Network-based andreinforcement-based learning mechanisms) and machine learning algorithmsto learn from experience what objects or people that are within animage, thereby improving accuracy of recognition over time.

The recognition component 430 provides (as represented by arrow 439) thesensed features into a sensed feature store 440, which can store thesensed features (and associated confidence levels) for each physicalentity within the location 401, whether the physical entity is withinthe physical space for a short time, a long time, or permanently. Thecomputation component 450 may then perform a variety of queries and/orcomputations on the sensed feature data provided in sensed feature store440. The queries and/or computations may be enabled by interactions(represented by arrow 449) between the computation component 450 and thesensed feature store 440.

When the recognition component 430 senses a sensed feature of a physicalentity within the location 401 using sensor signal(s) provided by asensor, the sensor signals are also provided to a store, such as thesensed feature store. For instance, in FIG. 4, the sensed feature store440 is illustrated as including sensed features 441 as well as thecorresponding sensor signals 442 that represent the evidence of thesense features.

The computation component 450 may also have a security component 451that may determine access to data with the sensed feature store 440. Forinstance, the security component 451 may control which users may accessthe sensed feature data 441 and/or the sensor signals 442. Furthermore,the security component 451 may even control which of the sensed featuredata that computations are performed over, and/or which user areauthorized to perform what type of computations or queries. Thus,security is effectively achieved.

Since the sensed feature data represents the sensed features of thephysical entities within the physical space 401 over time, complexcomputing may be performed on the physical entities within the physicalspace 401. As will be described below, for a user, it is as though thevery environment itself is filled with helpful computing power that isgetting ready for any computing query or computation regarding thatphysical space. This will be referred to hereinafter also as “ambientcomputing”.

Furthermore, whenever a sensed feature is of interest, the evidencesupporting that recognition component's sensing of that feature may bereconstructed. For instance, the computing component 440 might providevideo evidence of when a particular physical entity first entered aparticular location. If multiple sensors generated sensor signals thatwere used by the recognition component to sense that feature, then thesensor signals for any individual sensor or combination of sensors maybe reconstructed and evaluated. Thus, for instance, the video evidenceof the physical entity first entering a particular location may bereviewed from different angles.

The physical space 401 is illustrated in FIG. 4 and is intended just tobe an abstract representation of any physical space that has sensors init. There are infinite examples of such physical spaces, but examplesinclude a room, a house, a neighborhood, a factory, a stadium, abuilding, a floor, an office, a car, an airplane, a spacecraft, a Petridish, a pipe or tube, the atmosphere, underground spaces, caves, land,combinations and/or portions thereof. The physical space 401 may be theentirety of the observable universe or any portion thereof so long asthere are sensors capable of receiving signals emitted from, affected by(e.g., diffraction, frequency shifting, echoes, etc.), and/or reflectedfrom the physical entities within the location.

The physical entities 410 within the physical space 401 are illustratedas including four physical entities 411, 412, 413 and 414 by way ofexample only. The ellipses 415 represent that there may be any numberand variety of physical entities having features that are being sensedbased on data from the sensors 420. The ellipses 415 also represent thatphysical entities may exit and enter the location 401. Thus, the numberand identity of physical entities within the location 401 may changeover time.

The position of the physical entities may also vary over time. Thoughthe position of the physical entities is shown in the upper portion ofthe physical space 401 in FIG. 4, this is simply for purpose of clearlabelling. The principles described herein are not dependent on anyparticular physical entity occupying any particular physical positionwithin the physical space 401.

Lastly, for convention only and to distinguish physical entities 410from the sensors 420, the physical entities 410 are illustrated astriangles and the sensors 420 are illustrated as circles. The physicalentities 410 and the sensors 420 may, of course, have any physical shapeor size. Physical entities typically are not triangular in shape, andsensors are typically not circular in shape. Furthermore, sensors 420may observe physical entities within a physical space 401 without regardfor whether or not those sensors 420 are physically located within thatphysical space 401.

The sensors 420 within the physical space 401 are illustrated asincluding two sensors 421 and 422 by way of example only. The ellipses423 represent that there may be any number and variety of sensors thatare capable of receiving signals emitted, affected (e.g., viadiffraction, frequency shifting, echoes, etc.) and/or reflected by thephysical entities within the physical space. The number and capabilityof operable sensors may change over time as sensors within the physicalspace are added, removed, upgrade, broken, replaced, and so forth.

FIG. 5 illustrates a flowchart of a method 500 for tracking physicalentities within a physical space. Since the method 500 may be performedto track the physical entities 410 within the physical space 401 of FIG.4, the method 500 of FIG. 5 will now be described with frequentreference to the environment 400 of FIG. 4. Also, FIG. 6 illustrates anentity tracking data structure 600 that may be used to assist inperforming the method 500, and which may be used to later performqueries on the tracked physical entities, and perhaps also to access andreview the sensor signals associated with the tracked physical entities.Furthermore, the entity tracking data structure 600 may be stored in thesensed feature store 440 of FIG. 6 (which is represented as sensedfeature data 441). Accordingly, the method 500 of FIG. 5 will also bedescribed with frequent reference to the entity tracking data structure600 of FIG. 6.

In order to assist with tracking, a space-time data structure for thephysical space is set up (act 501). This may be a distributed datastructure or a non-distributed data structure. FIG. 6 illustrates anexample of an entity tracking data structure 600 that includes aspace-time data structure 601. This entity tracking data structure 600may be included within the sensed feature store 440 of FIG. 4 as sensedfeature data 441. While the principles described herein are describedwith respect to tracking physical entities, and their sensed featuresand activities, the principles described herein may operate to trackingphysical entities (and their sensed features and activities) within morethan one location. In that case, perhaps the space-time data structure601 is not the root node in the tree represented by the entity trackingdata structure 600 (as symbolized by the ellipses 602A and 602B). Ratherthere may be multiple space-time data structures that may beinterconnected via a common root node.

Then, returning to FIG. 5, the content of box 510A (the dotted-linedbox) may be performed for each of multiple physical entities (e.g.,physical entities 410) that are at least temporarily within a physicalspace (e.g., physical space 401). Furthermore, the content of box 510B(the dashed-lined box) is illustrated as being nested within box 510A,and represents that its content may be performed at each of multipletimes for a given physical entity. By performing the method 500, acomplex entity tracking data structure 600 may be created and grown, tothereby record the sensed features of physical entities that are one ormore times within the location. Furthermore, the entity tracking datastructure 600 may be used to access the sensed signals that resulted incertain sensed features (or feature changes) being recognized.

For a particular physical entity in the location at a particular time, aphysical entity is sensed by one or more sensors (act 511). In otherwords, one or more physical signals emitted from, affected by (e.g., viadiffraction, frequency shifting, echoes, etc.), and/or reflected fromthe physical entity is received by one or more of the sensors. Referringto FIG. 1, suppose that physical entity 411 has one or more featuresthat are sensed by both sensors 421 and 422 at a particular time.

One aspect of security may enter at this point. The recognitioncomponent 430 may have a security component 431 that, according toparticular settings, may refuse to record sensed features associatedwith particular physical entities, sensed features of a particular type,and/or that were sensed from sensor signals generated at particulartime, or combinations thereof. For instance, perhaps the recognitioncomponent 430 will not record sensed features of any people that arewithin the location. As a more fine-grained examples, perhaps therecognition component 430 will not record sensed features of a set ofpeople, where those sensed features relate to an identity or gender ofthe person, and where those sensed features resulted from sensor signalsthat were generated at particular time frames.

If permitted, an at least approximation of that particular time at whichthe physical entity was sensed is represented within an entity datastructure that corresponds to the physical entity and this iscomputing-associated with the space-time data structure (act 512). Forinstance, referring to FIG. 6, the entity data structure 610A maycorrespond to the physical entity 411 and is computing-associated (asrepresented by line 630A) with the space-time data structure 601. Inthis description and in the claims, one node of a data structure is“computing-associated” with another node of a data structure if acomputing system is, by whatever means, able to detect an associationbetween the two nodes. For instance, the use of pointers is onemechanism for computing-association. A node of a data structure may alsobe computing-associated by being included within the other node of thedata structure, and by any other mechanism recognized by a computingsystem as being an association.

The time data 611 represents an at least approximation of the time thatthe physical entity was sensed (at least at this time iteration of thecontent of box 510B) within the entity data structure 610A. The time maybe a real time (e.g., expressed with respect to an atomic clock), or maybe an artificial time. For instance, the artificial time may be a timethat is offset from real-time and/or expressed in a different mannerthan real time (e.g., number of seconds or minutes since the last turnof the millennium). The artificial time may also be a logical time, suchas a time that is expressed by a monotonically increasing number thatincrements at each sensing.

Also, based on the sensing of the particular physical entity at theparticular time (at act 511), the environment senses at least onephysical feature (and perhaps multiple) of the particular physicalentity in which the particular physical entity exists at the particulartime (act 513). For instance, referring to FIG. 4, the recognitioncomponent 430 may sense at least one physical feature of the physicalentity 411 based on the signals received from the sensors 421 and 422(e.g., as represented by arrow 429).

The sensed at least one physical feature of the particular physicalentity is then represented in the entity data structure (act 514) in amanner computing-associated with the at least approximation of theparticular time. For instance, in FIG. 4, the sensed feature data isprovided (as represented by arrow 439) to the sensed feature store 440.In some embodiments, this sensed feature data may be provided along withthe at least approximation of the particular time so as to modify theentity tracking data structure 600 in substantially one act. In otherwords, act 512 and act 514 may be performed at substantially the sametime to reduce write operations into the sensed feature store 440.

Furthermore, if permitted, the sensor signal(s) that the recognitioncomponent relied upon to sense the sensed feature are recorded in amanner that is computer-associated with the sensed feature (act 515).For instance, the sensed feature that is in the sensed feature data 441(e.g., in the space-time data structure 601) may be computing-associatedwith such sensor signal(s) stored in the sensed signal data 442.

Referring to FIG. 6, the first entity data structure now has sensedfeature data 621 that is computing-associated with time 611. In thisexample, the sensed feature data 621 includes two sensed physicalfeatures 621A and 621B of the physical entity. However, the ellipses621C represents that there may be any number of sensed features of thephysical entity that is stored as part of the sensed feature data 621within the entity data structure 601. For instance, there may be asingle sensed feature, or innumerable sensed features, or any numberin-between for any given physical entity as detected at any particulartime.

In some cases, the sensed feature may be associated with other features.For instance, if the physical entity is a person, the feature might be aname of the person. That specifically identified person might have knowncharacteristics based on features not represented within the entity datastructure. For instance, the person might have a certain rank orposition within an organization, have certain training, be a certainheight, and so forth. The entity data structure may be extended by, whena particular feature is sensed (e.g., a name), pointing to additionalfeatures of that physical entity (e.g., rank, position, training,height) so as to even further extend the richness of querying and/orother computation on the data structure.

The sensed feature data may also have confidence levels associated witheach sensed feature, that represents an estimated probability that thephysical entity really has the sensed feature at the particular time610A. In this example, confidence level 621 a is associated with sensedfeature 621A and represents a confidence that the physical entity 411really has the sensed feature 621A. Likewise, confidence level 621 b isassociated with sensed feature 621B and represents a confidence that thephysical entity 411 really has the sensed feature 621B. The ellipses 621c again represents that there may be confidence levels expressed for anynumber of physical features. Furthermore, there may be some physicalfeatures for which there is no confidence level expressed (e.g., in thecase where there is certainty or in case where it is not important ordesirable to measure confidence of a sensed physical feature).

The sensed feature data also has computing-association (e.g., a pointer)to the sensor signal(s) that were used by the recognition component tosense the sense feature of that confidence level. For instance, in FIG.6, sensor signal(s) 621Aa is computing-associated with sensed feature621A and represents the sensor signal(s) that were used to sense thesensed feature 621A at the time 611. Likewise, sensor signal(s) 621Bb iscomputing-associated with sensed feature 621B and represents the sensorsignal(s) that were used to sense the sensed feature 621B at the time611. The ellipses 621Cc again represents that there may becomputing-associations of any number of physical features.

The security component 431 of the recognition component 430 may alsoexercise security in deciding whether or not to record sensor signal(s)that were used to sense particular features at particular times. Thus,the security component 431 may exercise security in 1) determiningwhether to record that particular features were sensed, 2) determiningwhether to record features associated with particular physical entities,3) determining whether to record features sensed at particular times, 4)determining whether to record the sensor signal(s), and if so whichsignals, to record as evidence of a sensed feature.

As an example, suppose that the location being tracked is a room. Nowsuppose that an image sensor (e.g., a camera) senses something withinthe room. An example sensed feature is that the “thing” is a humanbeing. Another example sensed feature is that the “thing” is aparticular named person. There might be a confidence level of 100percent that the “thing” is a person, but only a 20 percent confidencelevel that the person is a specific identified person. In this case, thesensed feature set includes one feature that is a more specific type ofanother feature. Furthermore, the image data from the camera may bepointed to by the record of the sensed feature of the particularphysical entity at the particular time.

Another example feature is that the physical entity simply exists withinthe location, or at a particular position within the location. Anotherexample is that this is the first appearance of the physical entitysince a particular time (e.g., in recent times, or even ever). Anotherexample of features is that the item is inanimate (e.g., with 99 percentcertainty), a tool (e.g., with 80 percent certainty), and a hammer(e.g., with 60 percent certainty). Another example feature is that thephysical entity is no longer present (e.g., is absent) from thelocation, or has a particular pose, is oriented in a certain way, or hasa positional relationship with another physical entity within thelocation (e.g., “on the table” or “sitting in chair #5”).

In any case, the number and types of features that can be sensed fromthe number and types of physical entities within any location isinnumerable. Also, as previously mentioned, as represented by box 510B,the acts within box 510B may potentially be performed multiple times forany given physical entity. For instance, physical entity 411 may beagainst detected by one or both of sensors 421 and 422. Referring toFIG. 6, this detection results in the time of the next detection (or isapproximation) to be represented within the entity data structure 610.For instance, time 612 is also represented within the entity datastructure. Furthermore, sensed features 622 (e.g., including perhapssensed feature 622A and 622B—with ellipses 622C again representingflexibility) are computing-associated with the second time 612.Furthermore, those sensed features may also have associated confidencelevels (e.g., 622 a, 622 b, ellipses 622 c). Likewise, those sensedfeatures may also have associated sensor signals (e.g., 622Aa, 622Bb,ellipses 622Cc).

The sensed features sensed at the second time may be the same as ordifferent than the sensed features sensed at the first time. Theconfidence levels may change over time. As an example, suppose a humanbeing is detected at time #1 at one side of a large room via an imagewith 90 percent confidence, and that the human being is specificallysensed as being John Doe with 30 percent confidence. Now, at time #2that is 0.1 seconds later, John Doe is sensed 50 feet away at anotherpart of the room with 100 percent confidence, and there remains a humanbeing at the same location where John Doe was speculated to be at time1. Since human beings do not travel 50 feet in a tenth of a second (atleast in an office setting), it can now be concluded that the humanbeing detected at time 1 is not John Doe at all. So that confidence fortime #1 that the human being is John Doe is reduced to zero.

In that case, the sensed feature can be safely removed from the entityfor time 1, since we now know that the sensed human being at time 1 wasnot John Doe after all. In one embodiment, a cleanup component providesfor garbage collection of the sensed feature data 441 and the sensorsignal data 442. For instance, if there are no longer any sensedfeatures that are associated with a particular sensor signal, thatparticular sensor signal might perhaps be removed. If a sensed featurehas a confidence level at or below a certain level, the sensed featuredata of that low or zero confidence level may be removed from the sensedfeature data. If sensed feature data or sensor signal data is stale(e.g., generated a long time ago), that data might perhaps be removed.In this manner, rather than have the sensed feature data 441 and thesensor signal data 442 grow unceasingly, the size of such data may bemore carefully managed.

Returning to FIG. 4, the ellipses 613 and 623 represent that there is nolimit to the number of times that a physical entity may be detectedwithin the location. As subsequent detections are made, more may belearned about the physical entity, and thus sensed features may be added(or removed) as appropriate, with corresponding adjustments toconfidence levels for each sensed feature.

Now moving outside of box 510B, but remaining within box 510A, for anygiven physical entity, feature changes in the particular entity may besensed (act 522) based on comparison (act 521) of the sensed feature(s)of the particular physical entity at different times. This sensedchanges may be performed by the recognition component 430 or thecomputation component 450. If desired, those sensed changes may also berecorded (act 523). For instance, the sensed changes may be recorded inthe entity data structure 610A in a manner that is, or perhaps is not,computing-associated with a particular time. Sensor signals evidencingthe feature change may be reconstructed using the sensor signals thatevidenced the sensed feature at each time.

For instance, based on a sensed feature at a first time being a presenceof the physical entity within the location, and based on a secondfeature at a second time being an absence of the physical entity withinthe location, it can be concluded that the physical entity has exitedthe physical space. On the contrary, based on a sensed feature at afirst time being an absence of the physical entity from the location,and a second feature at a second time being a presence of the physicalentity within the location, it can be concluded that the physical entityhas entered the location. In some case, perhaps absence from a physicalspace is not looked for in a physical entity until the physical entityis first detected as being present in the physical space.

Now referring to the box 510A, this tracking of feature(s) of physicalentities may be performed for multiple entities over time. For instance,the content of box 510A may be performed for each of physical entities411, 412, 413 or 414 within the physical space 401 or for other physicalentities that enter or exit the physical space 401. Referring to FIG. 6,the space-time data structure 601 also is computing-associated (asrepresented by lines 630B, 630C, and 630D) with a second entity datastructure 610B (perhaps associated with the second physical entity 412of FIG. 4), a third entity data structure 610C (perhaps associated withthe third physical entity 413 of FIG. 4); and a fourth entity datastructure 610D (perhaps associated with the fourth physical entity 414of FIG. 4).

The space-time data structure 401 may also include one or more triggersthat define conditions and actions. When the conditions are met,corresponding actions are to occur. The triggers may be stored at anylocation in the space-time data structure. For instance, if theconditions are/or actions are with respect to a particular entity datastructure, the trigger may be stored in the corresponding entity datastructure. If the conditions and/or actions are with respect to aparticular feature of a particular entity data structure, the triggermay be stored in the corresponding feature data structure.

The ellipses 610E represent that the number of entity data structuresmay change. For instance, if tracking data is kept forever with respectto physical entities that are ever within the physical space, thenadditional entity data structures may be added each time a new physicalentity is detected within the location, and any given entity datastructure may be augmented each time a physical entity is detectedwithin the physical space. Recall, however, that garbage collection maybe performed (e.g., by clean-up component 460) to keep the entitytracking data structure 600 from growing too large to be properlyedited, stored and/or navigated.

Outside of the box 510A, physical relationships between differentphysical entities may be sensed (act 532) based on comparison of theassociated entities data structures (act 531). Those physicalrelationships may likewise be recorded in the entity tracking datastructure 601 (act 533) perhaps within the associated entity datastructures that have the sensed physical relationships, and/or perhapsassociated with the time that the physical entities are sensed as havingthe relationship. For instance, by analysis of the entity datastructures for different physical entities through time, it might bedetermined that at a particular time, that a physical entity may behidden behind another physical entity, or that a physical entity may beobscuring the sensing of another physical entity, or that two physicalentities have been joined or that a physical entity has been detached tocreate multiple physical entities. Sensor signals evidencing thephysical entity relationship may be reconstructed using the sensorsignals that evidenced the sensed feature at the appropriate time andfor each physical entity as described with respect to FIG. 7.

The feature data store 440 may now be used as a powerful store uponwhich to compute complex functions and queries over representations ofphysical entities over time within a physical space. Such computationand querying may be performed by the computation component 450. Thisenables enumerable numbers of helpful embodiments, and in factintroduces an entirely new form of computing referred to herein as“ambient computing”. Within the physical space that has sensors, it isas though the very air itself can be used to compute and sense stateabout the physical world. It is as though a crystal ball has now beencreated for that physical space from which it is possible to queryand/or compute many things about that location, and its history.

As an example, a user may now query whether an object is right now in aphysical space, or where an object was at a particular time within thephysical space. The user might also query which person having particularfeatures (e.g., rank or position within a company) is near that objectright now, and communicate with that person to bring the object to theuser. The user might query as to relationships between physicalentities. For instance, the user might query who has possession of anobject. The user might query as to the state of an object, whether it ishidden, and what other object is obscuring view of the object. The usermight query when a physical entity first appeared within the physicalspace, when they exited, and so forth. The user might also query whenthe lights were turned off, when the system became certain of one ormore features of a physical entity. The user might also search onfeature(s) of an object. The user might also query on activities thathave occurred within the location. A user might compute the mean timethat a physical entity of a particular type is within the location,anticipate where a physical entity will be at some future time, and soforth. Accordingly, rich computing and querying may be performed on aphysical space that has sensors.

FIG. 7 illustrates a flowchart of a method 700 for efficiently renderingsignal segments of interest. First, the computing system navigates thenavigable graph of sensed features to reach a particular sensed feature(act 701). For instance, this navigation may be performed automatic orin response to user input. The navigation may be the result of acalculation, or may simply involve identifying the sensed feature ofinterest. As another example, the navigation may be the result of a userquery. In some embodiments, a calculation or query may result inmultiple sensed features being navigated to. As an example, suppose thatthe computing system navigates to sensed feature 422A in FIG. 4.

The computing system then navigates to the sensed signalcomputer-associated with the particular sensed feature (act 702) usingthe computer-association between the particular sensed feature and theassociated sensor signal. For instance, in FIG. 4, with the sensedfeature being sensed feature 422A, the computer-association is used tonavigate to the signal segment 422Aa.

Finally, the signal segment may then be rendered (act 703) on anappropriate output device. For instance, if the computing system is thecomputing system 100 of FIG. 1, the appropriate output device might beone or more of output mechanisms 112A. For instance, audio signals maybe rendered using speakers, and visual data may be rendered using adisplay. After navigating to the sensed signal(s), multiple things couldhappen. The user might play a particular signal segment, or perhapschoose from multiple signal segments that contributed to the feature. Aview could be synthesized from the multiple signal segments.

With computing being performed on the physical world, a new type ofambient computation is enabled. It is as though computers are availablein the very ambient environment, embodied within the air itself, andable to perform computations on physical entities that were at any pointin contact with that air. In the workplace, productivity may be greatlyimproved using this ambient computing. For instance, a user may quicklyfind a misplaced tool, or be able to communicate with a peer close tothe tool so that the user can ask that peer to grab that tool and bringit to the user. Furthermore, in addition to ambient computing, humanbeings may review the sensor signal(s) that were used to sense featuresof interest for particular physical entities of interest, at particulartimes of interest. As with any revolutionary breakthrough in technology,the technology must be used responsibly. However, the number ofscenarios for improving physical productivity by due to responsible useof ambient computing is limitless.

The present invention may be embodied in other specific forms withoutdeparting from its spirit or essential characteristics. The describedembodiments are to be considered in all respects only as illustrativeand not restrictive. The scope of the invention is, therefore, indicatedby the appended claims rather than by the foregoing description. Allchanges which come within the meaning and range of equivalency of theclaims are to be embraced within their scope.

What is claimed:
 1. A computing system for performing a method formanaging sensed signals used to sense features of physical entities overtime, the system comprising: one or more processors; one or morecomputer-readable media having thereon computer-executable instructionsthat, when executed by the one or more processors, cause the computingsystem to perform the method for managing sensed signals used to sensefeatures of physical entities over time, the method comprising: creatinga computer-navigable graph of a plurality of sensed features of aplurality of sensed physical entities over a plurality of times, thesensed features determined from analysis of sensor signals observed ofthe plurality of sensed physical entities; and for at least one of thesensed features of at least one of the sensed plurality of entities,associating within the computer-navigable graph a signal segment withthe at least one sensed feature such that computer-navigation to thesensed feature also allows for computer-navigation to the signalsegment, wherein the associated signal segment is a particular signalsegment of the at least one sensed entity which had been analyzed todetermine the at least one sensed feature.
 2. The computing system inaccordance with claim 1, the signal segment comprising an identificationof a sensor that resulted in sensing of the sensed feature.
 3. Thecomputing system in accordance with claim 2, the signal segmentexcluding at least one or more signal segments from the identifiedsensor that were not used to sense the sensed feature.
 4. The computingsystem in accordance with claim 1, the signal segment comprising a videosignal, the signal segment comprising one or more frames of a videosignal generated by a sensor.
 5. The computing system in accordance withclaim 4, wherein for at least one of the frames of the video signal, thesignal segment includes just a portion of the frame.
 6. The computingsystem in accordance with claim 1, the signal segment comprising animage signal captured by a sensor.
 7. The computing system in accordancewith claim 6, the signal segment including just a portion of the imagecaptured by the sensor.
 8. The computing system in accordance with claim1, the sensed signal being an audio signal captured by a sensor.
 9. Thecomputing system in accordance with claim 1, the sensed signal being afiltered version of a signal captured by a sensor.
 10. The computingsystem in accordance with claim 9, the filtered version being filteredby frequency.
 11. The computing system in accordance with claim 1, thesensed signal being transformed.
 12. The computing system in accordancewith claim 1, the method further comprising: navigating the navigablegraph to a particular sensed feature of the plurality of features; andnavigating to the sensed signal computer-associated with the particularsensed feature using the computer-association between the particularsensed feature and the associated sensor signal.
 13. The computingsystem in accordance with claim 12, the navigating the navigable graphto the particular sensed feature being performed in response to userinput.
 14. The computing system in accordance with claim 13, thenavigating to the sensed signal occurring automatically upon performingthe act of navigating to the particular sensed feature.
 15. Thecomputing system in accordance with claim 13, the navigating to thesensed signal occurring in response to user input received after the actof navigating the navigable graph to the particular sensed feature. 16.The computing system in accordance with claim 12, the navigating to theparticular sensed feature being performed in response to a user query.17. The computing system in accordance with claim 12, the method furthercomprising rendering the sensed signal.
 18. A computer implementedmethod for managing sensed signals used to sense features of physicalentities over time, the method comprising: executing computer-executableinstructions on one or more processors of a computing system, therebycausing the computing system to perform the method comprising: creatinga computer-navigable graph of a plurality of sensed features of aplurality of sensed physical entities over a plurality of times, thesensed features determined from analysis of sensor signals observed ofthe plurality of sensed physical entities; and for at least one of thesensed features of at least one of the sensed plurality of entities,associating within the computer-navigable graph a signal segment withthe at least one sensed feature such that computer-navigation to thesensed feature also allows for computer-navigation to the signalsegment, wherein the associated signal segment is a particular signalsegment of the at least one sensed entity which had been analyzed todetermine the at least one sensed feature.
 19. The method in accordancewith claim 18, further comprising: navigating the navigable graph to aparticular sensed feature of the plurality of features; and navigatingto the sensed signal computer-associated with the particular sensedfeature using the computer-association between the particular sensedfeature and the associated sensor signal.
 20. A computer program productfor managing sensed signals used to sense features of physical entitiesover time, the computer program product comprising one or morecomputer-readable storage media having thereon computer-executableinstructions that, when executed by one or more processors of acomputing system, cause the computing system to perform a method formanaging sensed signals used to sense features of physical entities overtime, the method comprising: creating a computer-navigable graph of aplurality of sensed features of a plurality of sensed physical entitiesover a plurality of times, the sensed features determined from analysisof sensor signals observed of the plurality of sensed physical entities;and for at least one of the sensed features of at least one of thesensed plurality of entities, associating within the computer-navigablegraph a signal segment with the at least one sensed feature such thatcomputer-navigation to the sensed feature also allows forcomputer-navigation to the signal segment, wherein the associated signalsegment is a particular signal segment of the at least one sensed entitywhich had been analyzed to determine the at least one sensed feature.